CN114318637B - Integrated intelligent broad water-jet loom - Google Patents

Abstract

The invention discloses an integrated intelligent wide water-jet loom, which comprises a loom main body, and an output shaft and a winding shaft which are arranged in the loom main body in parallel, wherein the bottom of the loom main body is detachably provided with a mounting seat, a guide roller parallel to the output shaft is arranged in the mounting seat, a dust absorption mechanism is also arranged between the guide roller and the winding shaft, the bottom of the mounting seat is provided with a moving device, the moving device comprises a moving platform and a lead screw driving structure for driving the moving platform to move in the mounting seat simultaneously in the transverse direction and the longitudinal direction, and the moving platform is fixedly connected with a rack; plant a nail device of fixed mounting in the frame, plant the activity in the nail device and placed a plurality of banding nails, the banding nail is through planting equidistant activity joint to the cloth edge of nail device. The length of the guide roller and the length of the dust absorption mechanism can be adjusted according to the width of the cloth, the inner dust absorption plate and the outer dust absorption plate are in a negative pressure state through the negative pressure pump, and dust on the surface of the cloth is absorbed and cleaned through the dust absorption holes.

Description

Integrated intelligent broad water-jet loom

Technical Field

The invention relates to the technical field of wide water-jet loom equipment, in particular to an integrated intelligent wide water-jet loom.

Background

Water jet looms are shuttleless looms which use jets of water to pull the weft shed. The friction traction force of the water-jet weft insertion to the weft yarn is larger than that of the air-jet weft insertion, the diffusivity is small, and the requirements of long-wire weft insertion such as synthetic fiber and glass fiber with smooth surfaces are met. Meanwhile, the conductivity of the composite fiber can be increased, and static electricity in weaving can be effectively overcome. In addition, the energy consumed by weft yarn injection is less, the noise is lowest, and compared with the traditional shuttle loom, the efficiency of the water jet loom is greatly improved, so that more profit spaces are brought to enterprises.

In the use process of the existing water-jet loom, in order to realize the processing of multiple wide-width cloth, the guide rollers are usually adjusted aiming at the cloth with different widths, and meanwhile, the existing water-jet loom is easy to be contaminated by dust in the winding process to influence the quality. For this reason, an integrated intelligent broad water jet loom is proposed to solve the above problems.

Disclosure of Invention

The invention aims to provide an integrated intelligent wide-width water-jet loom to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an integrated intelligent wide water-jet loom comprises a loom main body, an output shaft and a winding shaft which are arranged in the loom main body in parallel, wherein a mounting seat is detachably arranged at the bottom of the loom main body, a guide roller parallel to the output shaft is arranged in the mounting seat, and cloth output from the output shaft bypasses the guide roller and then is wound back to the winding shaft;

a dust absorption mechanism is arranged between the guide roller and the winding shaft, the dust absorption mechanism and the guide roller are arranged on the same machine frame, and the lengths of the dust absorption mechanism and the guide roller are adjusted according to the width of the cloth;

the bottom of the mounting seat is provided with a moving device, the moving device comprises a moving table and a lead screw driving structure for driving the moving table to move transversely and longitudinally in the mounting seat at the same time, and the moving table is fixedly connected with the rack;

the utility model discloses a cloth edge sealing device, including the frame of dust absorption mechanism, be located one of them side of dust absorption mechanism, plant the banding nail device of fixed mounting in the frame, plant the banding nail of nail device internalization and placed a plurality of U types, the banding nail is through planting equidistant activity joint to the cloth edge of nail device.

Preferably, the guide roller is composed of two outer shafts arranged in parallel and two inner shafts movably inserted in the outer shafts, the end parts of the outer shafts and the inner shafts are rotatably connected with the frame, and the end part of the frame is also provided with a driving mechanism for driving the two inner shafts to synchronously and reversely rotate.

Preferably, the dust collection mechanism is composed of two outer dust collection plates arranged in parallel and two inner dust collection plates arranged in parallel, the inner dust collection plates are movably inserted into the outer dust collection plates, dust collection holes which are uniformly distributed are formed in the inner side surfaces of the outer dust collection plates and the inner dust collection plates, communicated cavities are formed in the outer dust collection plates and the inner dust collection plates, and one sides of the cavities are communicated with the negative pressure pump through hoses.

Preferably, the screw driving structure in the moving device comprises two parallel transverse screws and two parallel longitudinal screws, the two transverse screws are in threaded connection with first sliding blocks, a first guide rod is connected between the two first sliding blocks, and the first guide rod longitudinally and movably penetrates through the moving table;

the two longitudinal screw rods are in threaded connection with second sliding blocks, a second guide rod is connected between the second sliding blocks, and the second guide rod transversely and movably penetrates through the mobile station;

the two transverse lead screws rotate simultaneously through the belt transmission structure, and the two longitudinal lead screws rotate simultaneously through the belt transmission structure, so that the position of the mobile station in the mounting seat is controlled.

Preferably, the nail planting device comprises a screening cavity, a feed hopper, a blanking cavity and a nail pushing mechanism, wherein the feed hopper and the blanking cavity are respectively communicated with the upper part and the lower part of the screening cavity;

the nail pushing mechanism comprises a nail pushing plate communicated with the blanking cavity, a cavity is arranged in the nail pushing plate, a V-shaped outlet cavity is formed in the end portion of the cavity, the size of the outlet cavity is gradually reduced, a pushing block capable of sliding freely is arranged at the other end of the nail pushing plate, and an ejector rod is fixedly connected to one side, facing the edge sealing nail, of the pushing block.

Preferably, the screening cavity is of a hollow cylindrical cavity structure, a cover plate is detachably mounted on the outer side of the screening cavity, a rotating ring is coaxially and rotatably mounted in the screening cavity, the rotating ring is driven by a motor mounted on the back of the screening cavity, the distance between the rotating ring and the inner wall of the screening cavity is smaller than the length of the edge sealing nail, four nail grooves are centrally and symmetrically mounted on the rotating ring, and a limiting block is arranged on one side of each nail groove in the rotating direction of the rotating ring in a protruding mode;

fixed disk of coaxial fixed mounting on the apron, the fixed disk is embedded to the swivel becket middle part, and the swivel becket rotates for the fixed disk, sets up a slide along unloading chamber axis on the fixed disk, and the banding nail can slide in the unloading intracavity along the slide, and unloading chamber and feeder hopper lie in same one side in screening chamber, and constitute V type structure.

Compared with the prior art, the invention has the beneficial effects that:

the length of the guide roller and the dust absorption mechanism can be adjusted according to the width of the cloth, the inner dust absorption plate and the outer dust absorption plate are in a negative pressure state through the negative pressure pump, and dust on the surface of the cloth is absorbed and cleaned through the dust absorption holes.

According to the invention, through two screening modes aiming at the edge sealing nails in different directions, the edge sealing nails sliding out of the blanking cavity are ensured to be opened outwards, so that the edge sealing nails can be conveniently clamped to the edge of cloth in the follow-up process;

according to the invention, the edge sealing nails are movably clamped to the edge of the cloth at equal intervals through the nail implanting device, and the interval between every two edge sealing nails can be the actually required interval, so that the length of the cloth is determined by determining the number of the edge sealing nails, and the cloth can be conveniently cut at the later stage.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a part of the structure of the present invention;

FIG. 3 is a schematic diagram of a mobile device according to the present invention;

FIG. 4 is a schematic view of a dust suction mechanism according to the present invention;

FIG. 5 is a schematic view of a dust-collecting plate according to the present invention;

FIG. 6 is a schematic view of the nail-implanting device of the present invention;

FIG. 7 is an exploded view of the nail-implanting device of the present invention;

FIG. 8 is a schematic view of a rotating ring according to the present invention;

FIG. 9 is a schematic view of a fixing plate of the present invention;

FIG. 10 is a schematic view of a first state in the screening chamber of the present invention;

FIG. 11 is a schematic view of a second state in the screening chamber of the present invention

FIG. 12 is a schematic view of a third state in the screening chamber of the present invention

FIG. 13 is a diagram illustrating a fourth state in the screening chamber according to the present invention

FIG. 14 is a schematic view of a staple pushing mechanism of the present invention.

In the figure: 1. a loom main body; 101. an output shaft; 102. a winding shaft; 103. a mounting base;

2. a guide roller; 21. an outer shaft; 22. an inner shaft; 23. a drive mechanism; 231. a gear; 232. a third motor; 201. a frame;

3. a mobile device; 31. a transverse lead screw; 32. a first slider; 33. a first guide bar; 34. a longitudinal lead screw; 35. a second slider; 36. a second guide bar; 37. a mobile station; 38. a first belt pulley; 39. a first drive belt; 310. a first motor; 311. a second belt reel; 312. a second belt; 313. a second motor;

4. a dust suction mechanism; 41. an outer dust collection plate; 42. an inner dust absorption plate; 43. a dust collection hole; 44. a hose;

5. a nail planting device; 51. a screening chamber; 5101. a cover plate; 52. a feed hopper; 53. fixing the disc; 5301. a slideway; 54. a rotating ring; 5401. a nail groove; 5402. a limiting block; 55. a blanking cavity; 56. a nail pushing mechanism; 561. a nail pushing plate; 562. an outlet chamber; 563. a push block; 564. a push rod; 565. a rotating rod; 566. a fourth motor; 567. ejecting the rod;

6. and (6) edge sealing nails.

Detailed Description

The technical solution of the present invention will be described below with reference to the accompanying drawings and examples.

Referring to fig. 1, the present invention provides a technical solution: an integrated intelligent wide water-jet loom comprises a loom main body 1, an output shaft 101 and a winding shaft 102, wherein the output shaft 101 and the winding shaft 102 are arranged in the loom main body 1 in parallel, a mounting seat 103 is detachably arranged at the bottom of the loom main body 1, a guide roller 2 parallel to the output shaft 101 is arranged in the mounting seat 103, and cloth output from the output shaft 101 bypasses the guide roller 2 and then winds back to the winding shaft 102. The loom body 1 of the invention adopts a conventional wide water-jet loom in the field, and aims at the dust collection and cleaning processes after cloth output.

Specifically, referring to fig. 2-5, a dust suction mechanism 4 is further disposed between the guide roller 2 and the winding shaft 102, the dust suction mechanism 4 and the guide roller 2 are mounted on the same frame 201, and the lengths of the dust suction mechanism 4 and the guide roller 2 are adjusted according to the width of the fabric.

The guide roller 2 is composed of two parallel outer shafts 21 and two inner shafts 22 movably inserted in the outer shafts 21, the ends of the outer shafts 21 and the inner shafts 22 are rotatably connected with the frame 201, and a driving mechanism 23 for driving the two inner shafts 22 to synchronously and reversely rotate is further arranged at the end of the frame 201.

In an embodiment of the present invention, in order to enable the inner shaft 22 to rotate and simultaneously drive the outer shaft 21 to rotate, a groove is formed on the surface of the inner shaft 22 along the axis of the inner shaft, a rib is arranged on the inner wall of the inner shaft 22 and is matched with the groove, and the rib is slidably clamped in the groove to limit the relative degree of freedom of the outer shaft 21 and the inner shaft 22 in the radial direction.

The inner shaft 22 can slide freely in the outer shaft 21, thereby adjusting the length of the guide roller 2 to adapt to different widths of cloth.

In an embodiment of the present invention, the driving mechanism 23 is composed of two gears 231 connected to the end of the inner shaft 22 and a third motor 232 driving one of the gears 231 to rotate, the end of the inner shaft 22 rotates to penetrate through the frame 201, a shield is detachably mounted on the outer side of the frame 201, and the two gears 231 are engaged with each other and located in the shield. When the third motor 232 drives one of the gears 231 to rotate, the two inner shafts 22 rotate simultaneously in opposite directions, so as to convey the cloth toward the dust suction mechanism 42.

As shown in fig. 4-5, the dust suction mechanism 4 is composed of two outer dust suction plates 41 arranged in parallel and two inner dust suction plates 42 arranged in parallel, the inner dust suction plate 42 is movably inserted into the outer dust suction plates 41, dust suction holes 43 uniformly distributed are formed on the inner side surfaces of the outer dust suction plates 41 and the inner dust suction plates 42, communicated cavities are formed inside the outer dust suction plates 41 and the inner dust suction plates 42, and one side of each cavity is communicated with a negative pressure pump through a hose 44.

The ends of the two outer suction plates 41 and the two inner suction plates 42 are fixedly connected to the side of the frame 201, a gap is provided between the opposite surfaces of the two outer suction plates 41, and cloth is fed from the guide roller 2 to between the two outer suction plates 41. The inside of the outer dust suction plate 41 and the inside dust suction plate 42 is in a negative pressure state by the negative pressure pump, and dust on the surface of the cloth is absorbed and cleaned by the dust absorption holes 43.

The outer dust-collecting plate 41 is screwed with a locking bolt, and the locking bolt penetrates through the outer wall of the outer dust-collecting plate 41 and contacts the outer surface of the inner dust-collecting plate 42, so that the outer dust-collecting plate 41 and the inner dust-collecting plate 42 are fixed after being stretched.

The length of the guide roller 2 and the length of the dust suction mechanism 4 can be adjusted according to the width of the cloth, wherein the middle part of the rack 201 is also provided with a telescopic rod-shaped structure, and a bolt structure for locking is arranged on the rod-shaped structure.

Referring to fig. 2-3, the moving device 3 is disposed at the bottom of the mounting base 103, the moving device 3 includes a moving platform 37 and a screw driving structure for driving the moving platform 37 to move horizontally and longitudinally in the mounting base 103, and the moving platform 37 is fixedly connected to the frame 201.

The screw driving structure in the moving device 3 comprises two parallel transverse screws 31 and two parallel longitudinal screws 34, the two transverse screws 31 are connected with first sliders 32 in a threaded manner, a first guide rod 33 is connected between the two first sliders 32, and the first guide rod 33 longitudinally and movably penetrates through a moving table 37;

the two longitudinal screw rods 34 are in threaded connection with second sliding blocks 35, a second guide rod 36 is connected between the second sliding blocks 35, and the second guide rod 36 transversely and movably penetrates through a moving table 37;

the two transverse screws 31 are rotated simultaneously by the belt transmission structure, and the two longitudinal screws 34 are rotated simultaneously by the belt transmission structure, thereby controlling the position of the movable table 37 in the mounting seat 103.

Referring to fig. 3, in an embodiment of the present invention, the end portions of the two transverse screws 31 are respectively provided with a first belt pulley 38, the two first belt pulleys 38 located on the same side are driven by a first driving belt 39, and any one of the first belt pulleys 38 is further connected to a driving disc of the first motor 310 by a belt; two second belt pulleys 311 positioned on the same side are driven by a second driving belt 312, and any one of the second belt pulleys 311 is also in driving connection with a driving disc of a second motor 313 through a belt. When the first motor 310 and the second motor 313 are started, the transverse lead screw 31 and the longitudinal lead screw 34 can be driven to rotate, the moving table 37 can freely slide on the first guide rod 33 and the second guide rod 36, so that the multi-directional movement of the moving table 37 is realized, the guide roller 2 and the dust suction mechanism 4 are further driven to move below the loom main body 1, and the cloth with different widths is also adapted.

As shown in fig. 2, 4, and 6-9, a nail planting device 5 is fixedly installed on the frame 201 on one side of the dust suction mechanism 4, a plurality of U-shaped edge sealing nails 6 are movably placed in the nail planting device 5, and the edge sealing nails 6 are movably clamped to the edge of the cloth through the nail planting device 5 at equal intervals.

In one embodiment of the invention, the nail planting device 5 comprises a screening chamber 51, a feed hopper 52 and a blanking chamber 55 which are respectively communicated with the upper part and the lower part of the screening chamber 51, and a nail pushing mechanism 56, wherein the edge sealing nails 6 are poured from the upper part of the feed hopper 52, are screened in the screening chamber 51, keep the same opening direction and are input into the blanking chamber 55,

as shown in fig. 14, the staple pushing mechanism 56 includes a staple pushing plate 561 communicated with the blanking cavity 55, a cavity is provided in the staple pushing plate 561, a V-shaped exit cavity 562 is provided at an end of the cavity, the size of the exit cavity 562 is gradually reduced, a freely sliding push block 563 is provided at the other end of the staple pushing plate 561, and an ejection rod 567 is fixedly connected to one side of the push block 563 facing the edge sealing staple 6.

The push block 563 slides reciprocally in the ejector pin plate 561 under the action of the power structure. In one embodiment of the present invention, referring to fig. 14, the power structure comprises a push rod 564 rotatably connected to the top of the push block 563 and a rotation rod 565 rotatably connected to the push rod 564, wherein the other end of the rotation rod 565 is fixedly connected to the driving end of the fourth motor 566. The rotating rod 565 is driven to rotate by the fourth motor 566, so that the push rod 564 drives the push block 563 to reciprocate, and the edge sealing nail 6 in the nail pushing plate 561 is pushed to the outlet cavity 562 by the ejector rod 567. Because the opening of the outlet cavity 562 is gradually reduced, the upper edge and the lower edge of the edge sealing nail 6 are extruded, so that the edge sealing nail 6 can be directly clamped at the edge of the cloth in the extruding process from the outlet cavity 562.

In practice, the interval time for ejecting the edge sealing nails 6 is kept constant, and meanwhile, the ejecting speed of the ejection rod 567 can be controlled by adjusting the rotating speed of the fourth motor 566, so that the interval distance between two adjacent edge sealing nails 6 clamped on the cloth is controlled. The distance between every two edge sealing nails 6 can be 1, 2 or 3 meters or other actually required distances, so that the length of the cloth can be determined by determining the number of the edge sealing nails 6, and the cloth can be conveniently cut at the later stage.

The screening cavity 51 is of a hollow cylindrical cavity structure, a cover plate 5101 is detachably mounted on the outer side of the screening cavity 51, a rotating ring 54 is coaxially and rotatably mounted in the screening cavity 51, the rotating ring 54 is driven by a motor mounted on the back of the screening cavity 51, the distance between the rotating ring 54 and the inner wall of the screening cavity 51 is smaller than the length of the edge sealing nail 6, four nail grooves 5401 are centrally and symmetrically mounted on the rotating ring 54, and a limiting block 5402 is arranged on one side of each nail groove 5401 in the rotating direction of the rotating ring 54 in a protruding mode;

a fixed disc 53 is coaxially and fixedly installed on the cover plate 5101, the fixed disc 53 is embedded in the middle of the rotating ring 54, the rotating ring 54 rotates relative to the fixed disc 53, a slideway 5301 along the axis of the blanking cavity 55 is arranged on the fixed disc 53, the edge sealing nail 6 can slide into the blanking cavity 55 along the slideway 5301, and the blanking cavity 55 and the feed hopper 52 are positioned on the same side of the screening cavity 51 and form a V-shaped structure.

The edge banding nails 6 put into the feed hopper 52 are irregular, and the edge banding nails 6 actually sliding out of the feed cavity 55 into the nail pushing plate 561 need to be opened outwards. Therefore, after the edge banding nails 6 enter the screening chamber 51 from the feeding hopper 52, the following steps are performed (see fig. 10-13):

the rotating ring 54 is driven by the motor to rotate in the screening chamber 51 in a counterclockwise manner;

if the edge banding nail 6 slides out of the feed hopper 52 in an upward opening mode and falls into one of the nail grooves 5401, the edge banding nail 6 is perpendicular to the axis of the slideway 5301, and the edge banding nail 6 rotates to a position parallel to the axis of the slideway 5301 along with the rotating ring 4. At this time, the edge sealing nail 6 has an opening facing downward and is just clipped into the outer side of the limiting block 5402, as shown in fig. 11, the edge sealing nail 6 cannot slide into the slide 5301. Until the seaming pin 6 follows the rotating ring 54 above the blanking chamber 55, at which point the seaming pin 6 opens upwards and slides downwards along the blanking chamber 55.

If the edge sealing nail 6 slides out of the feed hopper 52 in a mode that the opening of the edge sealing nail 6 faces downwards and falls into one of the nail grooves 5401, the edge sealing nail 6 is perpendicular to the axis of the slideway 5301, and the edge sealing nail 6 rotates to a position parallel to the axis of the slideway 5301 along with the rotating ring 4. At this moment, the opening of the edge sealing nail 6 faces upwards, the edge sealing nail 6 cannot be clamped with the limiting block 5402, and the edge sealing nail 6 can directly slide into the blanking cavity 55 along the slide rail 5301.

Through the above-mentioned two kinds of screening methods to the banding nail 6 in different position, guarantee that the banding nail 6 from unloading chamber 55 roll-off all is the opening towards the outside, the cloth edge is connected to subsequent joint of being convenient for.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. The utility model provides an integral type intelligence broad width water jet loom, includes output shaft and the winding shaft in loom main part and the parallel arrangement loom main part, its characterized in that: the bottom of the loom main body is detachably provided with a mounting seat, a guide roller parallel to the output shaft is arranged in the mounting seat, and the cloth output from the output shaft bypasses the guide roller and then is wound back to the winding shaft;

a dust absorption mechanism is arranged between the guide roller and the winding shaft, the dust absorption mechanism and the guide roller are arranged on the same machine frame, and the lengths of the dust absorption mechanism and the guide roller are adjusted according to the width of the cloth;

the bottom of the mounting seat is provided with a moving device, the moving device comprises a moving table and a lead screw driving structure for driving the moving table to move transversely and longitudinally in the mounting seat at the same time, and the moving table is fixedly connected with the rack;

a nail planting device is fixedly arranged on the rack positioned on one side of the dust collection mechanism, a plurality of U-shaped edge sealing nails are movably placed in the nail planting device, and the edge sealing nails are movably clamped to the edge of the cloth at equal intervals through the nail planting device;

the nail planting device comprises a screening cavity, a feed hopper and a blanking cavity which are respectively communicated above and below the screening cavity, and a nail pushing mechanism; the nail pushing mechanism comprises a nail pushing plate communicated with the blanking cavity, a cavity is arranged in the nail pushing plate, a V-shaped outlet cavity is formed in the end portion of the cavity, the size of the outlet cavity is gradually reduced, a pushing block capable of sliding freely is arranged at the other end of the nail pushing plate, and an ejector rod is fixedly connected to one side, facing the edge sealing nail, of the pushing block;

the screening cavity is of a hollow cylindrical cavity structure, a cover plate is detachably mounted on the outer side of the screening cavity, a rotating ring is coaxially and rotatably mounted in the screening cavity and driven by a motor mounted on the back of the screening cavity, the distance between the rotating ring and the inner wall of the screening cavity is smaller than the length of the edge sealing nail, four nail grooves are centrally and symmetrically mounted on the rotating ring, and a limiting block is arranged on one side of each nail groove in the rotating direction of the rotating ring in a protruding mode;

fixed disk of coaxial fixed mounting on the apron, the fixed disk is embedded to the swivel becket middle part, and the swivel becket rotates for the fixed disk, sets up a slide along unloading chamber axis on the fixed disk, and the banding nail can slide in the unloading intracavity along the slide, and unloading chamber and feeder hopper lie in same one side in screening chamber, and constitute V type structure.

2. The integrated intelligent broad water jet loom of claim 1, wherein: the guide roller is composed of two outer shafts arranged in parallel and two inner shafts movably inserted in the outer shafts, the end parts of the outer shafts and the inner shafts are rotatably connected with the frame, and the end part of the frame is also provided with a driving mechanism for driving the two inner shafts to synchronously and reversely rotate.

3. The integrated intelligent broad water jet loom of claim 1, wherein: the dust collection mechanism is composed of two outer dust collection plates arranged in parallel and two inner dust collection plates arranged in parallel, the inner dust collection plates are movably inserted into the outer dust collection plates, dust collection holes which are uniformly distributed are formed in the inner side surfaces of the outer dust collection plates and the inner dust collection plates, communicated cavities are formed in the outer dust collection plates and the inner dust collection plates, and one sides of the cavities are communicated with a negative pressure pump through hoses.

4. The integrated intelligent broad water jet loom of claim 1, wherein: the screw driving structure in the moving device comprises two transverse screws arranged in parallel and two longitudinal screws arranged in parallel, the two transverse screws are in threaded connection with first sliding blocks, a first guide rod is connected between the two first sliding blocks at the same time, and the first guide rod longitudinally and movably penetrates through the moving table;

the two longitudinal screw rods are in threaded connection with second sliding blocks, a second guide rod is connected between the second sliding blocks, and the second guide rod transversely and movably penetrates through the mobile station;

the two transverse lead screws rotate simultaneously through the belt transmission structure, and the two longitudinal lead screws rotate simultaneously through the belt transmission structure, so that the position of the mobile station in the mounting seat is controlled.

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